CN115041065A - Novel vibration platform for producing low-heat-conduction molten tin bath bottom bricks and using method - Google Patents

Abstract

The invention discloses a novel vibration platform for producing a low-heat-conduction tin bath bottom brick and a using method, belonging to the technical field of bottom brick production, and comprising a vibration seat, wherein a limiting pendant is fixedly arranged on the top surface of the vibration seat, a vibration material shell is arranged on the top surface of the vibration seat, shell outer grooves are respectively arranged on the outer walls of two sides of the vibration material shell, a plurality of structure reinforcing blocks are fixedly arranged in the shell outer grooves, a limiting inner sliding groove is arranged on the inner wall of the vibration material shell, a material groove is arranged in the vibration material shell, and a material guide assembly is slidably arranged on the inner wall of the material groove; according to the invention, the material guide assembly and the material turning assembly are arranged in the material guide device, so that the uniformity and the comprehensiveness of the material feeding can be ensured when the material feeding device is used for feeding the material, the material can be turned while the material is vibrated, the material can be mixed more uniformly, the inertia of an object is used as the driving force, no additional energy is needed, the using effect is good, and the cost is low.

Description

Novel vibration platform for producing low-heat-conduction molten tin bath bottom bricks and using method

Technical Field

The invention belongs to the technical field of bottom brick production, and particularly relates to a novel vibration platform for producing a low-heat-conduction tin bath bottom brick and a use method.

Background

When carrying out bottom brick production, often need mix to the raw materials, the raw materials after mixing can accord with the production requirement of bottom brick, at present when mixing to the raw materials, adopts some large-scale machines, stirs, though can reach good mixed effect but these mechanical cost are too high, are not suitable for middle-size and small-size enterprise, consequently need the raw materials mixing that the production of bottom brick is realized to a low cost vibration platform.

Some vibration platforms now produce the effect to the homogeneous mixing of raw materials through the vibration of platform purely, this process though can make the raw materials mix, but efficiency is extremely low, the effect is also not good, for this reason, people have increased the mixed degree of consistency and the effect that various compounding mechanisms improve the raw materials, but often add the occupation of land volume that equipment can improve whole equipment, increase the equipment energy consumption simultaneously, can't reach a more excellent solution, in order to effectively solve above-mentioned problem, need urgent need for novel low heat conduction tin bath bottom brick production with vibration platform and application method.

Disclosure of Invention

The invention aims to: in order to solve some present vibration platforms and produce the effect to the homogeneous mixing of raw materials through the vibration of platform, this process though can make the raw materials mix, but efficiency is extremely low, the effect is also not good, for this reason, people have increased the mixed degree of consistency and the effect that various compounding mechanisms improve the raw materials, but often add equipment and can improve the volume of taking up an area of whole equipment, increase equipment energy consumption simultaneously, can't reach the problem of a more excellent solution, and the novel vibration platform and the use method are used in production of low heat conduction tin bath bottom brick of proposing.

In order to achieve the purpose, the invention adopts the following technical scheme: novel low heat conduction molten tin bath bottom brick production is with vibration platform, including the vibration seat, fixed mounting has spacing pendant on the top surface of vibration seat, be provided with vibration material shell on the top surface of vibration seat, all be provided with the shell outer tank on the both sides outer wall of vibration material shell, fixed mounting has a plurality of structure bosses in the shell outer tank, be provided with spacing interior spout on the inner wall of vibration material shell, the inside of vibration material shell is provided with the silo, slidable mounting has the guide subassembly on the inner wall of silo, and the guide subassembly is used for adding the automatic both sides guide of raw materials, rotate on the inner wall of silo and install the stirring subassembly, the stirring subassembly is used for adding the autostable stirring of raw materials.

As a further description of the above technical solution:

the material guiding assembly comprises a material guiding triangular seat, side installation sliding blocks are fixedly installed on the outer walls of the two sides of the material guiding triangular seat, and meshing racks are fixedly installed at the two ends of each side installation sliding block.

As a further description of the above technical solution:

the one end fixed mounting of meshing rack has the side-mounting spring, sliding connection between side-mounting slider and the spacing inner chute, one end of side-mounting spring and one side inner wall fixed connection of spacing inner chute, be provided with the guide membrane on the guide triangle seat, the guide membrane is used for the quick conduction of raw materials.

As a further description of the above technical solution:

the material overturning assembly comprises a material overturning shaft, the material overturning shaft is rotatably installed on the inner wall of the trough, one end of the material overturning shaft is fixedly provided with meshing outer teeth, the meshing outer teeth are located in a side shell cavity of the vibrating shell, the meshing outer teeth are meshed with the meshing rack, and material overturning blades are fixedly installed outside the material overturning shaft.

As a further description of the above technical solution:

the automatic material stirring device is characterized in that a pressure-bearing material mixing mechanism is slidably mounted on the inner wall of the trough below the material guide assembly and used for automatic material stirring processing of raw materials, the pressure-bearing material mixing mechanism comprises a pressure-bearing plate, a pressure-bearing spring rod is fixedly mounted at the bottom of the pressure-bearing plate, the bottom end of the pressure-bearing spring rod is fixedly connected with the inner wall of the bottom of the trough, and a built-in threaded hole is formed in the pressure-bearing plate.

As a further description of the above technical solution:

the material mixing device is characterized in that a material mixing component is rotatably mounted on the inner wall of the bottom surface of the trough and comprises a material stirring shaft, a threaded bottom shaft is fixedly mounted at the bottom end of the material stirring shaft, and the threaded bottom shaft is rotatably connected with the inner wall of the bottom surface of the trough.

As a further description of the above technical solution:

the material stirring device is characterized in that a material stirring plate is fixedly mounted on the outer portion of the material stirring shaft, a plurality of material holes are formed in the material stirring plate, and the threaded bottom shaft and the built-in threaded hole are in threaded connection with each other.

As a further description of the above technical solution:

fixed mounting has two screens strips on the framework top surface of vibration material shell, and the inlay card installs locating component between two screens strips, and locating component is used for the quick stable installation of vibration material shell on the vibration seat, locating component includes the locating plate, the inside of locating plate is provided with the slide opening, and slidable mounting has the location couple in the slide opening, the bottom and the spacing pendant of location couple articulate each other.

As a further description of the above technical solution:

the outside fixed mounting of location couple has fastening gasket and lower card, fastening gasket and lower card are closely laminated with the upper and lower surface of locating plate respectively, the top fixed mounting of location couple has the screw thread end axle, hexagon nut is installed to the outside screw thread of screw thread end axle, hexagon nut and fastening gasket contact each other and the extrusion.

The invention also discloses a use method of the novel vibration platform for producing the low-heat-conduction tin bath bottom brick, which comprises the following steps:

s1, when the vibrating shell and the vibrating seat need to be quickly installed, the vibrating shell only needs to be installed on the vibrating seat, the positioning plate of the positioning assembly is clamped between the two clamping strips, then the bottom end of the positioning hook is mutually connected with the limiting hanging piece, and at the moment, the vibrating shell can be quickly positioned only by screwing the hexagon nut and the fastening gasket after the hexagon nut is installed;

s2, when materials are mixed, the raw materials are directly added into a material groove, the raw materials can be distributed to two sides through a material guide triangular seat of a material guide assembly at the moment, the vibration seat is driven to vibrate left and right, and in the vibration process, because the inertial material guide assembly can also move left and right, the material guide distribution of the raw materials can be more uniform in the moving process of the material guide assembly;

s3, in the moving process of the material guide assembly, a side-mounted spring can play a certain role in assisting movement, a meshing rack of the side-mounted spring can drive meshing external teeth meshed with the meshing rack to rotate, and at the moment, a material turning shaft can also rotate, so that material turning blades rotate, and the added and distributed raw materials are synchronously turned;

s4, in the material mixing process, along with the gradual addition and increase of raw materials, the raw materials fall on a pressure-bearing material mixing mechanism after being turned over primarily, the pressure borne by the pressure-bearing material mixing mechanism can be gradually increased, when the bearing pressure exceeds the bearing limit of a pressure-bearing spring rod, a bearing plate can slowly descend, and because the threaded bottom shaft of the material mixing component and a built-in threaded hole are in a mutual threaded connection relationship, the threaded bottom shaft can be driven to rotate in the displacement process of the bearing plate;

s5, stirring shaft and stirring plate synchronous rotation, the stirring plate can carry out further compounding to the raw materials and handle, and when the raw materials was great to the pressure that the stirring plate caused, a plurality of material hole in the accessible stirring plate passed through simultaneously, reduced the pressure to the stirring plate.

In summary, due to the adoption of the technical scheme, the invention has the beneficial effects that:

1. in the invention, the material guiding assembly and the material turning assembly are arranged in the material mixing device, when materials are mixed, the materials are directly added into the material tank, the materials can be respectively distributed to two sides through the material guiding triangular seats of the material guiding assembly, the vibration seat is simultaneously driven to vibrate left and right, during the vibration process, the material guiding assembly can also move left and right due to inertia, during the movement process of the material guiding assembly, the material guiding distribution of the materials can be more uniform, the uniformity during the material feeding is effectively ensured, simultaneously, during the movement process of the material guiding assembly, the side mounting spring can play a certain role of auxiliary movement, the meshing rack can drive the meshing outer teeth connected with the meshing rack to rotate, at the moment, the material turning shaft also rotates, so that the material turning blades rotate, the materials added and distributed are synchronously turned, through the linkage structure design, the uniformity and the comprehensiveness of the materials can be ensured during the material feeding of the device, simultaneously when vibrating to the raw materials, carry out the stirring to the raw materials, make more even that the raw materials can mix, and utilize the inertia of object as drive power, need not the extra energy, excellent in use effect, cost control is low.

2. In the invention, the pressure-bearing mixing mechanism is arranged in the mixing device, the raw materials can fall on the pressure-bearing mixing mechanism after primary stirring along with the gradual increase of the raw materials in the mixing process, the pressure borne by the pressure-bearing mixing mechanism can be gradually increased, when the bearing pressure exceeds the bearing limit of the pressure-bearing spring rod, the bearing plate can slowly descend, because the threaded bottom shaft of the mixing component and the built-in threaded hole are in a mutual threaded connection relationship, the threaded bottom shaft can be driven to rotate in the displacement process of the bearing plate, the stirring shaft and the stirring plate can be synchronously rotated, the stirring plate can further mix the raw materials, and meanwhile, when the pressure of the raw materials on the stirring plate is higher, the raw materials can pass through a plurality of material holes in the stirring plate, the pressure on the stirring plate is reduced, the stirring plate can be effectively protected, and by the structural design, the pressure of the raw materials is utilized to realize the mixing treatment of the raw materials, and the mixing uniformity and effectiveness of the equipment are further improved.

3. According to the vibration material shell positioning platform, the positioning assembly is arranged outside, when the vibration material shell and the vibration seat are required to be quickly installed, the vibration material shell is only required to be installed on the vibration seat, the positioning plate of the positioning assembly is clamped between the two clamping strips, the bottom end of the positioning hook is connected with the limiting hanging piece in a hanging mode, at the moment, after the hexagonal nut and the fastening gasket are only required to be installed, the vibration material shell can be quickly positioned by screwing the hexagonal nut, the vibration material shell is quick and convenient to install, meanwhile, the vibration material shell after installation is high in stability, displacement is not prone to occurring during vibration, and the overall using effect of the platform is improved.

Drawings

Fig. 1 is a schematic three-dimensional structure diagram of a vibration platform for producing a novel low-heat-conduction tin bath bottom brick.

FIG. 2 is an enlarged schematic perspective view of a vibrating shell in a vibrating platform for producing novel low-thermal-conductivity molten tin bath bottom bricks.

FIG. 3 is a schematic diagram of an enlarged explosion three-dimensional structure of a vibrating shell in a vibrating platform for producing novel low-heat-conductivity molten tin bath bottom bricks.

Fig. 4 is a schematic diagram of an enlarged explosion three-dimensional structure of a material guiding assembly and a material turning assembly in a vibration platform for producing a novel low-heat-conduction tin bath bottom brick.

FIG. 5 is a schematic diagram of an enlarged explosion three-dimensional structure of a pressure-bearing mixing mechanism in a vibration platform for producing novel low-heat-conductivity molten tin bath bottom bricks.

FIG. 6 is an enlarged schematic perspective view of a material mixing component in a vibration platform for producing a novel low-heat-conductivity molten tin bath bottom brick.

FIG. 7 is an enlarged schematic perspective view of a positioning assembly in a vibration platform for producing a novel low thermal conductivity molten tin bath bottom brick.

FIG. 8 is an enlarged schematic structural view of the A position in the vibration platform for producing the novel low-heat-conductivity molten tin bath bottom brick.

Illustration of the drawings:

1. a vibration seat; 2. vibrating the material shell; 3. a positioning assembly; 31. positioning a plate; 32. positioning the hook; 33. a threaded end shaft; 34. a hexagonal nut; 35. fastening a gasket; 4. a limiting hanging piece; 5. a structural reinforcement block; 6. a clamping strip; 7. a trough; 8. a material guiding assembly; 81. a material guiding triangular seat; 82. meshing the racks; 83. a spring is installed on the side; 84. a slide block is installed on the side; 9. a material overturning component; 91. meshing the outer teeth; 92. a material turning shaft; 93. turning over the material leaves; 10. a pressure-bearing mixing mechanism; 101. a mixing assembly; 1011. material holes; 1012. a kick-out plate; 1013. a threaded bottom shaft; 1014. a material stirring shaft; 102. a threaded hole is arranged inside; 103. a pressure bearing plate; 104. a pressure-bearing spring rod; 11. and an inner limiting chute.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-8, the present invention provides a technical solution: the novel vibration platform for producing the low-heat-conduction tin bath bottom brick comprises a vibration seat 1, wherein a limiting hanging piece 4 is fixedly installed on the top surface of the vibration seat 1, a vibration material shell 2 is arranged on the top surface of the vibration seat 1, shell outer grooves are formed in the outer walls of two sides of the vibration material shell 2, a plurality of structure reinforcing blocks 5 are fixedly installed in the shell outer grooves, a limiting inner sliding groove 11 is formed in the inner wall of the vibration material shell 2, a material groove 7 is arranged in the vibration material shell 2, a material guide assembly 8 is slidably installed on the inner wall of the material groove 7, the material guide assembly 8 is used for automatic two-side material guide for adding raw materials, a material overturning assembly 9 is rotatably installed on the inner wall of the material groove 7, and the material overturning assembly 9 is used for automatic stable material overturning for adding the raw materials;

the guide assembly 8 comprises a guide triangular seat 81, side-mounting sliders 84 are fixedly mounted on outer walls of two sides of the guide triangular seat 81, meshing racks 82 are fixedly mounted at two ends of the side-mounting sliders 84, side-mounting springs 83 are fixedly mounted at one ends of the meshing racks 82, the side-mounting sliders 84 are connected with the limiting inner chutes 11 in a sliding mode, one ends of the side-mounting springs 83 are fixedly connected with inner walls of the limiting inner chutes 11 in one side, guide films are arranged on the guide triangular seat 81, and the guide films are used for rapid conduction of raw materials.

The stirring assembly 9 comprises a stirring shaft 92, the stirring shaft 92 is rotatably installed on the inner wall of the trough 7, one end of the stirring shaft 92 is fixedly provided with meshing external teeth 91, the meshing external teeth 91 are located in a side shell cavity of the vibrating shell 2, the meshing external teeth 91 are meshed with the meshing rack 82, and stirring blades 93 are fixedly installed on the outer portion of the stirring shaft 92.

The specific implementation mode is as follows: when carrying out the compounding to the material, in directly adding silo 7 with the raw materials, the guide triangular seat 81 of raw materials accessible guide subassembly 8 distributes to both sides respectively this moment, drive vibration seat 1 takes place the horizontal vibration simultaneously, the vibration in-process, because inertia guide subassembly 8 also can control and take place to remove, guide subassembly 8 removes the in-process, can make the more even of raw materials guide distribution, at guide subassembly 8 removal in-process, side-mounting spring 83 can play certain supplementary effect of removing, its meshing rack 82 can drive the meshing external tooth 91 rotation rather than the meshing is connected, stirring axle 92 also can rotate this moment, thereby make stirring leaf 93 take place to rotate, carry out synchronous stirring to the raw materials of joining the distribution and handle.

A pressure-bearing mixing mechanism 10 is arranged below the material guide assembly 8 and on the inner wall of the material groove 7 in a sliding manner, the pressure-bearing mixing mechanism 10 is used for automatic material shifting treatment of raw materials, the pressure-bearing mixing mechanism 10 comprises a pressure-bearing plate 103, a pressure-bearing spring rod 104 is fixedly arranged at the bottom of the pressure-bearing plate 103, the bottom end of the pressure-bearing spring rod 104 is fixedly connected with the inner wall of the bottom surface of the trough 7, a built-in threaded hole 102 is arranged inside the pressure-bearing plate 103, a material mixing component 101 is rotatably arranged on the inner wall of the bottom surface of the material groove 7, the material mixing component 101 comprises a material stirring shaft 1014, the bottom end of the material stirring shaft 1014 is fixedly provided with a thread bottom shaft 1013, the thread bottom shaft 1013 is rotatably connected with the inner wall of the bottom surface of the material groove 7, a material shifting plate 1012 is fixedly arranged outside the material shifting shaft 1014, a plurality of material holes 1011 are arranged inside the material shifting plate 1012, and the threaded bottom shaft 1013 and the built-in threaded hole 102 are in threaded connection with each other.

The specific implementation mode is as follows; in the material mixing process, as the raw materials are added gradually and increased, the raw materials fall on the pressure-bearing material mixing mechanism 10 after passing through the primary material stirring, the pressure borne by the pressure-bearing material mixing mechanism 10 is gradually increased, when the bearing pressure of the pressure-bearing material mixing mechanism exceeds the bearing limit of the pressure-bearing spring rod 104, the bearing plate 103 slowly descends, because the threaded bottom shaft 1013 of the material mixing assembly 101 and the internally threaded hole 102 are in a mutual threaded connection relationship, in the displacement process of the bearing plate 103, the threaded bottom shaft 1013 can be driven to rotate, the material stirring shaft 1014 and the material stirring plate 1012 synchronously rotate, the material stirring plate 1012 can perform further material mixing processing on the raw materials, and when the pressure of the raw materials on the material stirring plate 1012 is higher, the raw materials can pass through a plurality of material holes 1011 in the material stirring plate 1012, and the pressure on the material stirring plate is reduced.

Fixed mounting has two screens strips 6 on vibrating material shell 2's the framework top surface, and the inlay card installs locating component 3 between two screens strips 6, and locating component 3 is used for vibrating material shell 2 rapid stabilization on vibration seat 1 to install, locating component 3 includes locating plate 31, the inside of locating plate 31 is provided with the slide opening, and slidable mounting has location couple 32 in the slide opening, location couple 32's bottom and spacing pendant 4 articulate each other, location couple 32's external fixation has fastening gasket 35 and lower card, fastening gasket 35 closely laminates with the upper and lower surface of locating plate 31 respectively with lower card, location couple 32's top fixed mounting has screw thread end shaft 33, hexagon nut 34 is installed to screw thread end shaft 33's outside screw thread, hexagon nut 34 and fastening gasket 35 contaction and extrusion each other.

The specific implementation mode is as follows: when needs will vibrate material shell 2 and the quick installation of vibration seat 1, only need to vibrate material shell 2 and install on vibration seat 1, block locating plate 31 of locating component 3 between two screens strip 6, make the bottom of location couple 32 and spacing pendant 4 articulate each other again, only need install behind hexagon nut 34 and the fastening gasket 35 this moment, can fix a position fast vibration material shell 2 through screwing hexagon nut 34.

The invention also discloses a use method of the novel vibration platform for producing the low-heat-conduction tin bath bottom brick, which comprises the following steps:

s1, when the vibrating shell 2 and the vibrating seat 1 need to be quickly installed, the vibrating shell 2 only needs to be installed on the vibrating seat 1, the positioning plate 31 of the positioning assembly 3 is clamped between the two clamping strips 6, then the bottom end of the positioning hook 32 is hooked with the limiting hanging piece 4, and at the moment, after the hexagonal nut 34 and the fastening gasket 35 are installed, the vibrating shell 2 can be quickly positioned by screwing the hexagonal nut 34;

s2, when materials are mixed, the raw materials are directly added into the material groove 7, the raw materials can be distributed to two sides through the material guide triangular seat 81 of the material guide assembly 8, the vibration seat 1 is driven to vibrate left and right, and in the vibration process, because the inertial material guide assembly 8 also moves left and right, the material guide distribution of the raw materials can be more uniform in the movement process of the material guide assembly 8;

s3, in the moving process of the material guiding assembly 8, the side mounting spring 83 can play a certain role in assisting movement, the meshing rack 82 can drive the meshing outer teeth 91 connected with the meshing rack to rotate, and the material turning shaft 92 can also rotate at the moment, so that the material turning blades 93 rotate, and the added and distributed raw materials are synchronously turned;

s4, in the material mixing process, along with the gradual increase of the raw materials, the raw materials fall on the pressure-bearing material mixing mechanism 10 after being turned through the primary material mixing, the pressure borne by the pressure-bearing material mixing mechanism 10 is gradually increased, when the bearing pressure of the pressure-bearing material mixing mechanism exceeds the bearing limit of the pressure-bearing spring rod 104, the pressure-bearing plate 103 slowly descends, and as the threaded bottom shaft 1013 of the material mixing assembly 101 and the internally threaded hole 102 are in a threaded connection relationship, the threaded bottom shaft 1013 can be driven to rotate in the displacement process of the pressure-bearing plate 103;

s5, the kick-out shaft 1014 and the kick-out plate 1012 rotate synchronously, the kick-out plate 1012 can further mix the raw materials, and meanwhile, when the pressure of the raw materials on the kick-out plate 1012 is large, the raw materials can pass through a plurality of material holes 1011 in the kick-out plate 1012, so that the pressure on the kick-out plate 1012 is reduced.

The working principle is as follows: when the vibrating material shell 2 and the vibrating seat 1 need to be quickly installed, the vibrating material shell 2 only needs to be installed on the vibrating seat 1, the positioning plate 31 of the positioning assembly 3 is clamped between the two clamping strips 6, then the bottom end of the positioning hook 32 is mutually hooked with the limiting hanging piece 4, and at the moment, after the hexagonal nut 34 and the fastening gasket 35 are installed, the vibrating material shell 2 can be quickly positioned by screwing the hexagonal nut 34; when materials are mixed, the raw materials are directly added into the material groove 7, the raw materials can be respectively distributed to two sides through the material guide triangular seats 81 of the material guide assembly 8, the vibration seat 1 is driven to vibrate left and right, and in the vibration process, the material guide assembly 8 can move left and right due to inertia, so that the material guide distribution of the raw materials can be more uniform in the moving process of the material guide assembly 8; in the moving process of the material guiding assembly 8, the side mounting spring 83 can play a certain role in assisting movement, the meshing rack 82 can drive the meshing outer teeth 91 connected with the meshing rack to rotate, and the material turning shaft 92 can also rotate at the moment, so that the material turning blades 93 rotate, and the added and distributed raw materials are synchronously turned; in the material mixing process, along with the gradual addition and increase of raw materials, the raw materials fall on the pressure-bearing material mixing mechanism 10 after being turned through primary material mixing, the pressure borne by the pressure-bearing material mixing mechanism 10 is gradually increased, when the bearing pressure of the pressure-bearing material mixing mechanism exceeds the bearing limit of the pressure-bearing spring rod 104, the bearing plate 103 is slowly lowered, and as the threaded bottom shaft 1013 of the material mixing component 101 and the built-in threaded hole 102 are in a mutual threaded connection relationship, the threaded bottom shaft 1013 can be driven to rotate in the displacement process of the bearing plate 103; the kick-out shaft 1014 and the kick-out plate 1012 rotate synchronously, the kick-out plate 1012 can further mix raw materials, and simultaneously when the pressure of the raw materials on the kick-out plate 1012 is large, the raw materials can pass through a plurality of material holes 1011 in the kick-out plate 1012, so that the pressure on the kick-out plate 1012 is reduced.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims (10)

1. Novel production of low heat conduction molten tin bath bottom brick is with vibration platform, including vibration seat (1), fixed mounting has spacing pendant (4), its characterized in that on the top surface of vibration seat (1): be provided with vibration material shell (2) on the top surface of vibration seat (1), all be provided with the shell outer tank on the both sides outer wall of vibration material shell (2), fixed mounting has a plurality of structure bosses (5) in the shell outer tank, be provided with spacing inner chute (11) on the inner wall of vibration material shell (2), the inside of vibration material shell (2) is provided with silo (7), slidable mounting has guide subassembly (8) on the inner wall of silo (7), and guide subassembly (8) are used for adding the automatic both sides guide of raw materials, rotate on the inner wall of silo (7) and install stirring subassembly (9), and stirring subassembly (9) are used for adding the autostable stirring of raw materials.

2. The novel vibration platform for producing the tin bath bottom brick with the low heat conductivity as claimed in claim 1, wherein the material guiding assembly (8) comprises a material guiding triangular seat (81), side installation sliding blocks (84) are fixedly installed on outer walls of two sides of the material guiding triangular seat (81), and meshing racks (82) are fixedly installed at two ends of each side installation sliding block (84).

3. The novel vibrating platform for producing the tin bath bottom brick with the low thermal conductivity according to claim 2, wherein one end of the meshing rack (82) is fixedly provided with a side mounting spring (83), the side mounting sliding block (84) is in sliding connection with the limiting inner sliding groove (11), one end of the side mounting spring (83) is fixedly connected with one side inner wall of the limiting inner sliding groove (11), and the material guiding triangular seat (81) is provided with a material guiding film which is used for rapidly conducting raw materials.

4. The novel vibrating platform for producing the low-heat-conductivity tin bath bottom brick as claimed in claim 3, wherein the stirring assembly (9) comprises a stirring shaft (92), the stirring shaft (92) is rotatably installed on the inner wall of the bath (7), one end of the stirring shaft (92) is fixedly provided with external meshing teeth (91), the external meshing teeth (91) are positioned in a side shell cavity of the vibrating shell (2), the external meshing teeth (91) are meshed with the meshing rack (82), and stirring blades (93) are fixedly installed on the outer part of the stirring shaft (92).

5. The novel vibration platform for producing the tin bath bottom brick with the low thermal conductivity according to claim 4, wherein a pressure-bearing mixing mechanism (10) is slidably mounted below the material guide assembly (8) on the inner wall of the material bath (7), the pressure-bearing mixing mechanism (10) is used for automatic material stirring processing of raw materials, the pressure-bearing mixing mechanism (10) comprises a pressure-bearing plate (103), a pressure-bearing spring rod (104) is fixedly mounted at the bottom of the pressure-bearing plate (103), the bottom end of the pressure-bearing spring rod (104) is fixedly connected with the inner wall of the bottom surface of the material bath (7), and a built-in threaded hole (102) is formed in the pressure-bearing plate (103).

6. The novel vibrating platform for producing the low-heat-conductivity tin bath bottom brick as claimed in claim 5, wherein a material mixing component (101) is rotatably mounted on the inner wall of the bottom surface of the material bath (7), the material mixing component (101) comprises a material stirring shaft (1014), a threaded bottom shaft (1013) is fixedly mounted at the bottom end of the material stirring shaft (1014), and the threaded bottom shaft (1013) is rotatably connected with the inner wall of the bottom surface of the material bath (7).

7. The novel vibration platform for producing the low-heat-conductivity molten tin bath bottom brick as claimed in claim 6, wherein a material stirring plate (1012) is fixedly installed outside the material stirring shaft (1014), a plurality of material holes (1011) are formed in the material stirring plate (1012), and the threaded bottom shaft (1013) and the internally threaded hole (102) are in threaded connection with each other.

8. The novel vibration platform for producing the low-heat-conductivity tin bath bottom brick as claimed in claim 7, wherein two clamping strips (6) are fixedly installed on the top surface of the frame body of the vibration material shell (2), a positioning component (3) is installed between the two clamping strips (6) in a clamping and embedding manner, the positioning component (3) is used for quickly and stably installing the vibration material shell (2) on the vibration seat (1), the positioning component (3) comprises a positioning plate (31), a sliding hole is formed in the positioning plate (31), a positioning hook (32) is installed in the sliding hole in a sliding manner, and the bottom end of the positioning hook (32) is hooked with the limiting hook (4).

9. The novel vibration platform for producing the low-heat-conductivity tin bath bottom brick as claimed in claim 8, wherein a fastening gasket (35) and a lower clamping piece are fixedly mounted on the outside of the positioning hook (32), the fastening gasket (35) and the lower clamping piece are respectively closely attached to the upper surface and the lower surface of the positioning plate (31), a threaded end shaft (33) is fixedly mounted on the top of the positioning hook (32), a hexagonal nut (34) is mounted on the external thread of the threaded end shaft (33), and the hexagonal nut (34) and the fastening gasket (35) are in contact with each other and extrude.

10. The use method of the novel vibration platform for the production of the low-heat-conductivity molten tin bath bottom brick as claimed in any one of claims 1 to 9, is characterized by comprising the following steps:

s1, when the vibrating shell (2) and the vibrating seat (1) are required to be installed quickly, the vibrating shell (2) is only required to be installed on the vibrating seat (1), the positioning plate (31) of the positioning assembly (3) is clamped between the two clamping strips (6), the bottom end of the positioning hook (32) is hooked with the limiting hanging piece (4) mutually, and at the moment, after the hexagonal nut (34) and the fastening gasket (35) are only required to be installed, the vibrating shell (2) can be positioned quickly by screwing the hexagonal nut (34);

s2, when materials are mixed, the raw materials are directly added into a material groove (7), the raw materials can be distributed to two sides through a material guide triangular seat (81) of a material guide assembly (8), the vibration seat (1) is driven to vibrate left and right, and in the vibration process, the material guide assembly (8) can move left and right due to inertia, so that the material guide distribution of the raw materials can be more uniform in the moving process of the material guide assembly (8);

s3, in the moving process of the material guide assembly (8), a side mounting spring (83) can play a certain role in auxiliary movement, a meshing rack (82) can drive a meshing outer tooth (91) in meshing connection with the side mounting spring to rotate, and at the moment, a material turning shaft (92) can also rotate, so that material turning blades (93) rotate, and the added and distributed raw materials are synchronously turned;

s4, in the material mixing process, along with the gradual addition and increase of raw materials, the raw materials fall on a pressure-bearing material mixing mechanism (10) after being subjected to primary material stirring, the pressure borne by the pressure-bearing material mixing mechanism (10) is gradually increased, when the bearing pressure exceeds the bearing limit of a pressure-bearing spring rod (104), a bearing plate (103) is slowly lowered, and due to the fact that the threaded bottom shaft (1013) of the material mixing assembly (101) and the built-in threaded hole (102) are in threaded connection, the threaded bottom shaft (1013) can be driven to rotate in the displacement process of the bearing plate (103);

s5, the kick-out shaft (1014) and the kick-out plate (1012) rotate synchronously, the kick-out plate (1012) can conduct further mixing processing on the raw materials, and meanwhile when the pressure of the raw materials on the kick-out plate (1012) is large, the raw materials can pass through a plurality of material holes (1011) in the kick-out plate (1012), and the pressure on the kick-out plate (1012) is reduced.

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